Compact elastic objects in general relativity
Abstract
We introduce a rigorous and general framework to study systematically self-gravitating elastic materials within general relativity, and apply it to investigate the existence and viability, including radial stability, of spherically symmetric elastic stars. We present the mass-radius () diagram for various families of models, showing that elasticity contributes to increase the maximum mass and the compactness up to , thus supporting compact stars with mass well above two solar masses. Some of these elastic stars can reach compactness as high as while remaining stable under radial perturbations and satisfying all energy conditions and subluminal wave propagation, thus being physically realizable models of stars with a light ring. We provide numerical evidence that radial instability occurs for central densities larger than that corresponding to the maximum mass, as in the perfect-fluid case. Elasticity may be a key ingredient to build consistent models of exotic ultracompact objects and black-hole mimickers, and can also be relevant for a more accurate modelling of the interior of neutron stars.
Keywords
Cite
@article{arxiv.2107.12272,
title = {Compact elastic objects in general relativity},
author = {Artur Alho and José Natário and Paolo Pani and Guilherme Raposo},
journal= {arXiv preprint arXiv:2107.12272},
year = {2022}
}
Comments
5 pages, 3 figures; v3: Inclusion of discussion regarding missing sound speed. Updated plot of Fig. 2 with previously missing velocity. Conclusions and results unchanged